2019-09-15T12:01:41ZTuning Gastropod Locomotion: Modeling The Influence Of Mucus Rheology on the Cost of Crawlinghttps://hdl.handle.net/1721.1/37326
Tuning Gastropod Locomotion: Modeling The Influence Of Mucus Rheology on the Cost of Crawling
Lauga, Eric; Hosoi, A.E.
Common gastropods such as snails crawl on a solid substrate by propagating muscular waves of shear stress on a viscoelastic mucus. Producing the mucus accounts for the largest component in the gastropod’s energy budget, more than twenty times the amount of mechanical work used in crawling. Using a simple mechanical model, we show that the shear-thinnning properties of the mucus favor
a decrease in the amount of mucus necessary for crawling, thereby decreasing the overall energetic cost of locomotion.
Submitted to Phys. Fluids.
2007-05-04T18:15:06ZExperimental Investigations of Elastic Tail Propulsion At Low Reynolds Numberhttps://hdl.handle.net/1721.1/37325
Experimental Investigations of Elastic Tail Propulsion At Low Reynolds Number
Yu, Tony S.; Lauga, Eric; Hosoi, A.E.
A simple way to generate propulsion at low Reynolds number is to periodically oscillate a passive flexible filament. Here we present a macroscopic experimental investigation of such a propulsive mechanism. A robotic swimmer is constructed and both tail shape and propulsive force are measured. Filament characteristics and the actuation are varied and resulting data are quantitatively compared with existing linear and nonlinear theories.
Accepted for publication in Phys. Fluids.
2007-05-04T18:14:22ZThe Flexure-based Microgap Rheometer (FMR)https://hdl.handle.net/1721.1/35772
The Flexure-based Microgap Rheometer (FMR)
Clasen, Christian; Gearing, Brian P.; McKinley, Gareth H.
We describe the design and construction of a new microrheometer designed to facilitate the viscometric study of complex fluids with very small sample volumes (1-10 μl)and gaps of micrometer dimensions. The Flexure-based Microgap Rheometer (FMR) is a
shear-rate-controlled device capable of measuring the shear stress in a plane Couette
configuration with directly-controlled gaps between 1 μm and 200 μm. White light
interferometry and a three-point nanopositioning stage using piezo-stepping motors are used to control the parallelism of the upper and lower shearing surfaces which are constructed from glass optical flats. A compound flexure system is used to hold the fluid sample testing unit between a drive spring connected to an ‘inchworm’ motor and an independent sensor spring. Displacements in the sensing flexure are detected using an inductive proximity sensor. Ready optical access to the transparent shearing surfaces enables monitoring of the structural evolution in the gap with a long working-distance video-microscope. This configuration then allows us to determine the microgap-dependent flow behavior of complex fluids over 5 decades of shear rate. We demonstrate the capability of the FMR by characterizing the complex stress and gap dependent flow behavior of a typical microstructured food product (mayonnaise) over the range of gaps from 8 to 100 μm and stresses from 10 to 1500 Pa. We correlate the gap-dependent rheological response to the microstructure of the emulsion and changes induced in the material by prolonged shearing.
Submitted to J. Rheol.
2007-01-23T12:07:15ZHow Dilute are Dilute Solutions in Extensional Flows?https://hdl.handle.net/1721.1/35771
How Dilute are Dilute Solutions in Extensional Flows?
Clasen, Christian; Plog, J.P.; Kulicke, W.-M.; Owens, M.; Macosko, C.; Scriven, L.E.; Verani, M.; McKinley, Gareth H.
We investigate the concentration-dependence of the characteristic relaxation time of
dilute polymer solutions in transient uniaxial elongational flow. A series of monodisperse polystyrene solutions of five different molecular weights (1.8×10^6 ≤ M ≤ 8.3×10^6 g/mol) with concentrations spanning five orders of magnitude were dissolved in two solvents of differing solvent quality (diethyl phthalate and oligomeric styrene). Optical measurements of the rate of filament thinning and the time to break-up in each fluid are used to determine the characteristic relaxation time. A lower sensitivity limit for the measurements was determined experimentally and confirmed by comparison to numerical calculations.
Above this sensitivity limit we show that the effective relaxation time of moderately
dilute solutions (0.01 ≤ c/c* ≤ 1) in transient extensional flow rises substantially above the fitted value of the relaxation time extracted from small amplitude oscillatory shear flow and above the Zimm relaxation time computed from kinetic theory and intrinsic viscosity
measurements. This effective relaxation time exhibits a power-law scaling with the reduced
concentration (c/c*) and the magnitude of the exponent varies with the thermodynamic quality of the solvent. This scaling appears to be roughly consistent to that predicted when the dynamics of the partially elongated and overlapping polymer chains are described within the framework of blob theories for semi-dilute solutions.
Submitted to J. Rheol.
2007-01-23T12:05:57Z